KR20040065510A - Connecting Structure and Connecting Method of Honeycomb Type Composite Beam Stiffened with Prestressed Concrete Panel - Google Patents

Abstract

PURPOSE: Structure for continuously connecting a precast concrete panel to a honeycomb girder steel beam and a continuous connecting method are provided to manage and maintain conveniently by increasing the span and reducing moment with assembling beams successively, and to improve comfortableness in traveling on the bridge by relieving tensile stress to the upper concrete slab with a tendon. CONSTITUTION: Two composite precast concrete panel beams(100) are placed at right and left sides of a shoe plate(201), and the shoe plate is combined with a sole plate(202). A joint connecting bottom plate is inserted between a web(101) of a steel beam and a concrete pouring part(50), and contacted to the lower part of the web by a height adjusting plate. A flange connection part(20) is formed by mounting upper and lower flange connecting plates(203,206) to a flange(104) with bolting, and a web connection part(30) is formed by combining the web with web connecting plates through bolting. The lower part of the web is welded into the upper part of the joint connecting bottom plate, and the joint connecting bottom plate is combined with a steel reinforcement bar. Non-shrinkage concrete(205) is poured in the form around the concrete pouring part, and an anchorage(111) is installed in a lower connecting plate(120). A tendon(113) is fastened to resist moment to the honeycomb girder connection part.

Description

Honeycomb girder-type precast concrete panel {Connecting Structure and Connecting Method of Honeycomb Type Composite Beam Stiffened with Prestressed Concrete Panel}

The present invention relates to a connection structure and a continuity method for sequencing a honeycomb girder-type precast concrete panel composite beam to construct a continuous bridge.

Conventionally, in order to continue the various beams installed in the bridge, beams in the form of simple beams are installed on each of the bridges or the top of the bridges, and the upper slab concrete is poured on each of the beams in the upper beams of the beams, and then each upper slab. For the concrete connection, a simple beam type is used to install the bridge expansion joint. However, in the simple beam type, the deflection is large and a large number of expansion joints are required, resulting in increased maintenance costs.

As a solution to overcome this, a continuous beam type without a bridge expansion joint is used by continuously placing the upper slab concrete by increasing the amount of reinforcing bar at the connection part of the upper concrete slab. When the continuous beam type is used, it is possible to economically design the cross section of the beam to save material, improve the shape and riding comfort of the bridge, and use only one bridge device in the continuous section. The maintenance costs associated with new joints can be reduced.

However, in the case of the conventional continuous beam type, since the reinforcing bar resists all the parent moments occurring in the continuous part, there is a fear of lack of workability such as reinforcement reinforcement and concrete sequential placing. In addition, since it is designed as a simple bridge while taking a continuous bridge shape, there is a limitation in section selection, and an adequate bending moment distribution effect cannot be expected, and thus, it is restricted in span extension. In addition, the number of shoes used (shoe) is large, there is a limit to improve the economics. There was also a problem of exposing the vulnerability to time dependent effects such as creep and shrinkage.

The present invention is to overcome the disadvantages and limitations of the prior art as described above, an object of the present invention is to increase the resistance to the parent moment acting on the bridge connection, to improve the workability, to save material and to maintain To make it convenient, it is to provide a continuous connection structure and a continuous method capable of appropriately coping with time-dependent effects such as creep and shrinkage.

1 is a perspective view of a honeycomb girder-type precast concrete panel composite beam connected by a connection structure and a continuous method according to the present invention.

2A is a cross-sectional view taken along the line A-A of FIG.

FIG. 2B is an enlarged view of the circle D portion of FIG. 2A. FIG.

2C illustrates another embodiment of FIG. 2B.

FIG. 2D is a sectional view of the tension support shown in FIGS. 1 and 2A.

Figure 2e is a sectional view showing another embodiment of the tension support.

3 is a cross-sectional view taken along line C-C of FIG. 2A;

4 is a cross-sectional view taken along the line B-B in FIG. 2A.

5 is a perspective view showing the internal structure of the concrete pouring portion and the internal structure of the precast concrete panel in the continuous honeycomb girder-type precast concrete panel composite beam shown in FIG.

Figure 6 is a perspective view of the bottom of the joint connection bottom plate facing up.

Figure 7 is a cross-sectional view showing a connection state of the general connection connecting base plate and the general connection connecting base plate is fixed.

Figure 8 is a perspective view of the general connecting base plate coupled to the tension member anchorage.

<Explanation of symbols for the main parts of the drawings>

10: soul plate portion 20: upper flange connection portion

30: abdominal connection 40: tension member reinforcement

50: concrete pouring

100: honeycomb girder precast concrete panel composite beam

101: abdomen of the steel beam 102: precast concrete panel

103: stud 104: flange of the steel beam

111: tension anchor

112: tension member auxiliary support 113: tension member

114: tension member support 114a: tension member support plate

114b: tension member receiving groove 120: general connection base plate

121: abdominal fastening plate 201: shoe plate

202: soul plate 203: flange connection top plate

204: abdominal connecting plate 205: non-contraction concrete

206: flange connection bottom plate 207: joint portion bottom plate

208: reinforcing bar 209: axial rebar

210: stub steel 211: stud

212: height control plate 213: spacer

214: stud 215: reinforced rib

216: fixing plate 217: tension member fixing hole

219: wedge 220: tension material

221: wedge groove 222: stud

In the present invention, in order to achieve the above object, as a continuous connection structure of the honeycomb girder-type precast concrete panel composite beam having a structure in which the honeycomb girder-type steel beam and the precast concrete panel is integrally assembled and synthesized, two neighboring The steel beams of the three honeycomb girder-type precast concrete panel composite beams are positioned so that the abdomens face each other, and a soul plate made of steel plates is provided on the lower end surface of the precast concrete panel, and each soul plate is composed of the composite beams. The precast concrete panels are coupled to each other so as to be integrally connected with each other so that the ends thereof are spaced apart at predetermined intervals by being coupled to a shoe plate installed at the connection portion of the beam; A joint connection bottom plate made of steel plates is disposed in the spaced space between the ends of the facing precast concrete panels, and the lower ends of the steel beam abdomens of the two side composite beams facing each other are integral with the joint connection bottom plate. The steel beams of both composite beams are integrally connected to each other; In order to connect the precast concrete panels of the composite beams on both sides of which are spaced apart from each other, the space between the two precast concrete panels on which the joint connecting base is located is placed with concrete so that the joint connecting base is embedded in the concrete. Both precast concrete panels are integrally connected with each other; Tension members are disposed on the composite beam connecting portions on both sides so that both ends are fixed to the lower portion of the steel beam at a position spaced apart from the connecting portion, and the middle portion thereof is supported by the upper side of the connecting portion of the steel beam. Provided is a continuous connection structure of a honeycomb girder type precast concrete panel composite beam, which is configured to apply a compressive force.

As a specific embodiment of the present invention, the tension member, both ends are fixed to the anchorage provided in the general connection connecting plate of the honeycomb girder-type precast concrete panel composite beam on both sides; The middle part is installed to be supported on the upper side of the abdominal connecting plate by the tension member support provided in the abdominal connecting plate connecting the abdomen of both composite beams to act on the continuous honeycomb girder type precast concrete panel composite beam. Honeycomb girder-type precast concrete, characterized in that configured to cancel the moment acting on the continuous honeycomb girder-type precast concrete panel composite beam by tensioning the tension member so that the opposite parent moment is generated to offset the cement. A continuous connection structure of panel composite beams is provided.

In the present invention as described above, the step is formed on the upper end surface of the both sides of the precast concrete panel is formed in a predetermined height inward, the joint connecting base plate is located in the step; The concrete that is poured and filled between the precast concrete panels of both synthetic beams to include the joint portion bottom plate is preferably made of non-concrete concrete.

On the other hand, in the present invention, as a connection method to form the above connection structure, two honeycomb girder type precast concrete panel composite beam is mounted on the left and right sides of the shoe plate, and the honeycomb girder type precast concrete panel composite beam is free of Coupling a sole plate, which is integrally provided at the bottom surface of the cast concrete panel, with the shoe plate; Push the joint connecting base plate into the space between the ends of the precast concrete panels of the opposite composite beams facing each other, and push the joint connecting base plate by using the height adjusting plate to connect the bottom of the steel beam abdomen of the composite beam and connect the joint part. Contacting the upper surface of the bottom plate; Connecting the flanges and the abdomen of both steel beams to each other; Integrally coupling an upper surface of the abdominal lower end of the steel beam closely contacted with an upper surface of the joint connection bottom plate; Placing concrete in a space between the ends of both precast concrete panels on which the joint connection bottom plates are disposed, thereby connecting the precast concrete panels and the joint connection bottom plates integrally; And a tension member disposed at both ends of the composite beam connecting portion so that both ends thereof are fixed to the lower portion of the steel beam at a position spaced apart from the connecting portion and the middle portion thereof is supported by the upper side of the connecting portion of the steel beam. Provided is a method for sequencing a honeycomb girder-type precast concrete panel composite beam, comprising the step of applying a compressive force by tension to the side.

In the above sequencing method, the installation and tensioning step of the tension member is specifically, the step of coupling the anchorage on the general connection base plate adjacent to the connection structure of the general connection base plate of the honeycomb girder-type precast concrete panel composite beam; Fixing one end to a fixing unit on one side, and arranging the tension member such that the middle part thereof spans the tension support provided on the upper side of the abdominal connection portion of the composite beam; And it may be configured to further include the step of fixing the tension member in the anchorage of the other side.

Hereinafter, the configuration of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view of a honeycomb girder type precast concrete panel composite beam 100 coupled using a connection structure according to the present invention, and FIG. 2A is a cross-sectional view taken along line AA of FIG. 1, FIG. 2B shows an enlarged cross-sectional view of the portion within circle D of FIG. 2A. 3 is a cross-sectional view taken along line C-C of FIG. 2A, and FIG. 4 is a cross-sectional view taken along line B-B of FIG. 2A. FIG. 5 is a perspective view showing the internal structure of the concrete placing portion and the internal structure of the precast concrete panel in the continuous honeycomb girder type precast concrete panel composite beam shown in FIG. 1.

As shown in FIG. 1, the connection structure of the honeycomb girder type precast concrete panel composite beam 100 of the present invention has a structure in which the honeycomb girder type steel beam and the precast concrete panel 102 are integrally assembled and synthesized. Honeycomb girder type precast concrete panel is used to continually synthesize the composite beam (100).

In the honeycomb girder type precast concrete panel composite beam 100 which is the object of the connection structure of the present invention, the coupling structure of the honeycomb girder type steel beam and the precast concrete panel 102 will be described later.

As shown in the figure, in the connecting structure of the present invention, the ends of both composite beams 100 to be connected to each other, the steel beam is in a state without the lower flange, the abdomen 101 of the steel beam at the connecting portion Both composite beams 100 are placed to face each other. At this time, the precast concrete panels 102 of both composite beams 100 are not facing each other and face each other at a predetermined interval.

On the other hand, as shown in Figure 4, both ends of the precast concrete panel 102 facing each other is formed a concave end of a predetermined height (H). The height H of the end is determined in consideration of the height and the clearance height of the joint connection bottom plate 207 which will be described later.

Soul plate portions 10 are integrally provided at both ends of the precast concrete panels 102 facing each other. The soul plate portion 10 is coupled to the shoe plate 201 made of a single steel plate is to connect both composite beams 100 to each other primarily. When the honeycomb girder type precast concrete panel composite beam 100 is installed on the pier, the shoe plate 201 is installed on the shoe of the pier.

The configuration of the soul plate portion 10, as shown in Figure 2a and 2b, and when using an unbonded PC strand (unbonded PC strand) as a tension material for the tension of the precast concrete panel 102 , As shown in Figure 2c, it is divided into the case of using a general PC steel wire or steel bar.

First, referring to FIGS. 2A and 2B, the configuration of the soul plate part 10 in the case of using a non-bonded PC steel wire is described. In the connection part of the composite beam 100, the lower surface of the end of the precast concrete panel 102 is formed. The sole plate 202 is provided, and the tension fixing plate 216 is connected to the soul plate 202 at a right angle. The soul plate 202 and the tension member fixing plate 216 are integrally attached to the precast concrete panel 102 when the composite beam 100 is prefabricated.

As described above, the soul plate 202 is a plate that is integrally coupled to the lower surface of the end of the precast concrete panel, the pre- so that it can be integrally coupled with the shoe plate 201 using a fastening means such as bolts. As shown in FIG. 1, the fastening portion protrudes out of the precast concrete panel 102, having a width larger than that of the cast concrete panel 102.

The tension member fixing hole 217 is formed in the tension member fixing plate 216, and an end portion of the tension member installed in the precast concrete panel 102 is fixed to the tension member fixing plate 216. In order to reinforce the connection between the soul plate 202 and the tension member fixing plate 216, a predetermined number of reinforcement ribs 215 may be provided between the soul plate 202 and the tension member fixing plate 216. Can be. On the other hand, a stud 211 is provided so that the soul plate 202 and the precast concrete panel 102 can be firmly coupled (see FIG. 4).

On the other hand, when using a general PC steel wire or steel rod as a tension material for the tension of the precast concrete panel 102, the soul plate portion 10, as shown in Figure 2c, the tension member fixing plate 216 Instead of using it, the wedge groove 221 is formed on the end face of the precast concrete panel and the end of the tension member 220 is buried in the wedge 219 to be fixed to the wedge groove 221. When the tension fixing plate 216 is not used, it is preferable to provide the stud 222 as the shear connector in the soul plate 202.

2C is a cross-sectional view of the middle of the precast concrete panel 102, the shape of the sole plate 202 and the shoe plate 201 is coupled by a fastening means such as a bolt, although not shown, FIG. Likewise, in the case of 2c, the soul plate 202 has a width larger than that of the precast concrete panel 102 to be integrally coupled with the shoe plate 201, as shown in FIG. 1. The fastening portion protrudes out of the precast concrete panel 102 so that the sole plate 202 and the shoe plate 201 are connected by the fastening means as shown in FIG. 2B.

As such, the soul plate portion 10 is coupled to the shoe plate 201 made of one steel plate, so that the adjacent both side synthetic beams 100 are aligned in a straight line with a space of a predetermined interval between both ends. do.

In the connection structure of the present invention, the upper flange of the honeycomb girder type precast concrete panel composite beam 10 is connected by a flange connection part 20, and the flange connection part 20 is formed of two adjacent honeycomb girder type steel beams. The flange connecting top plate 203 is overlapped on the upper part of the flange 104, and the flange connecting lower plate 206 is overlapped on the lower part of the flange 104, and then the flange connecting top plate 203 and the flange 104 are bolted. And the flange connecting lower plate 206 integrally connect the two steel beams.

On the other hand, the abdomen of the honeycomb girder-type precast concrete panel composite beam 10 is connected by an abdominal connector 30, the abdominal connector 30 is the abdomen on both sides of the abdomen 101 of the two adjacent steel beams The two steel beams are connected by overlapping the connecting plates 204 with bolts. In the drawings, reference numerals 20 and 30 denote upper flange connecting portions 20 and abdominal connecting portions 30 connecting the upper flanges and the abdomen of the steel beam by the above structure, respectively.

In the connection structure of the present invention, in addition to connecting both composite beams 100 by the sole plate portion 10, the upper flange connection portion 20 and the abdominal connection portion 30 is provided with a tension member reinforcement portion 40 as follows: By further reinforcing the connection state of both composite beams (100).

The tension member reinforcing portion 40 is a portion for placing and tensioning the tension member between the two adjacent composite beams 100, the specific configuration is as follows. The connecting base plate 120 (the connecting bottom plate will be described later) of both composite beams 100 is provided with a fixing unit 111 for fixing the tension member 113, and the abdominal connecting plate 204 is provided with a tension bar on the upper side thereof. Support 114 is installed. The tension member 113, such as a PC steel wire, a steel rod, etc., has a tension member support having a middle of the tension member 113 provided at the abdominal connecting plate 204 in a state where one end thereof is fixed to the fixing unit 111 of the one side composite beam 100 ( 114 and is tense so that the other end is fixed to the fixing unit 111 of the other side of the composite beam 100.

As described above, since the tension member 113 is disposed at the upper side of the composite beam 100 at the connection part to apply a tension force, the tension member 113 is applied to the tensile force due to the parent force generated at the connection part.

In the tension member reinforcement portion 40 as described above, it is preferable to secure the position of the tension member 113 by installing a tension member auxiliary support 112 between the fixing member 111 and the tension member support 114, the anchorage ( 111 is preferably to be able to perform both the role of fixing the tension member 113 and the role of tensioning the tension member 113.

In addition, the tension member support 114 is preferably provided with a configuration to prevent the tension member 113 from slipping to the outside, Figures 2d and 2e is the tension member 113 that spans the tension member support 114 is the tension member An embodiment of a configuration that prevents slipping out of the support 114 is shown in cross section.

As shown in FIG. 2D, the tension member accommodating groove 114b may be formed in the tension member support 114 so that the tension member 113 does not slip out of the tension member support 114. Alternatively, as illustrated in FIG. 2E, the tension member support plate 114 may be provided at the tension member support 114. However, the means for preventing slipping out of the tension member support 114 is not limited to the tension member receiving groove 114b or the tension member support plate 114a.

FIG. 5 illustrates a concrete pouring portion 50 in the state where the sole plate portion 10, the upper flange connection portion 20, the abdominal connection portion 30, and the tension reinforcing portion 40 are connected, and the precast concrete panel ( The internal structure of 102 is a perspective view shown in detail. 6 is a bottom perspective view of the joint connecting bottom plate 207.

As shown in FIG. 5, the precast concrete panel 102 is embedded with a plurality of stub steel reinforcement 210 and axial reinforcement 209 therein, and the concrete pour portion (so that the end can be connected by concrete pouring) 50) is formed. The concrete pouring portion 50 is a space between the precast concrete panels 102 of the opposite composite beam 100 facing each other, as described above, the upper end surface of the precast concrete panel 102 of a predetermined height A concave step may be formed.

The concrete pouring portion 50 is provided at the bottom of the abdomen 101 of the neighboring steel beams, the joint portion connecting base plate 207 for integrally connecting both steel beams is installed. The joint part bottom plate 207 is composed of a steel plate of a predetermined thickness.

As shown in FIG. 6, a plurality of studs 214 are provided at the bottom of the joint connection bottom plate 207 as a shear connecting material for anchors, and a predetermined number of height adjustment plates 212 are provided to the steel beams. The height of the abdomen 101, the lower end and the joint portion connecting bottom plate 207 is in close contact. In addition, a spacer may be used at the lower portion of the height adjusting plate 212 to firmly fix the height adjusting plate 212.

The joint part bottom plate 207 is integrally coupled to the abdomen 101 of the steel beam by welding the lower end of the abdomen 101 of the steel beam with the upper surface of the joint part bottom plate 207. Since the connection between the abdomen 101 of the steel beam and the joint connecting bottom plate 207 is made before the concrete is placed, there is no fear of cracking the concrete part due to the heat of welding.

Next, the point reinforcing reinforcing bars 208 are assembled and placed in the concrete pouring unit 50. As shown in FIGS. 4 and 5, the point reinforcing bars 208 are assembled into the bottom of the joint connection bottom plate 207 and at the same time, the stub bars are embedded in the precast concrete panel 102. Preferably connected to 210. It is preferable that a cover securing spacer 213 is provided between the joint part connecting bottom plate 207 and the point reinforcing bar 208.

When the above installation is completed, after the formwork is installed around the concrete pouring portion 50, the concrete 205 is poured and cured to complete the connection of the concrete pouring portion 50. As concrete to be poured into the concrete pouring portion 50, non-condensed concrete is preferable.

FIG. 7 is a cross-sectional view showing a connection state of the general connection bottom plate 120c and the general connection bottom plate 120 to which the tension member 113 is fixed.

In one example of the honeycomb girder type precast concrete panel composite beam 100 of the present invention, the precast concrete panel 102 is combined with a honeycomb steel beam in the following manner.

That is, the honeycomb girder-type steel beam, the cut portion cut into the abdomen in the abdomen is formed at a predetermined interval on the abdomen, the lower flange is not provided in the lower portion of the portion not cut in the abdomen 101 of the steel beam, The lower part of the portion not cut in the abdomen 101 of the steel beam is directly coupled to the general connection bottom plate 120 made of a steel plate of a predetermined thickness as shown in FIG. That is, the lower portion of the abdomen 101 of the steel beam is inserted into the vertical abdominal fastening plate 121 of the general connection bottom plate 120 and fastened by a fastening means such as a bolt to integrally connect the connection bottom plate 120 and the steel beam. Combined. Of course, the general connection bottom plate 120 is already installed in the precast concrete panel 102 at the time of manufacturing the precast concrete panel 102 is integrally provided.

Meanwhile, as shown in FIG. 7, when the length of the composite beam 100 is long, there may be a connection bottom plate on which the fixing part 111 is not provided in the general connection bottom plate 120. A fixing unit 111 is provided in the general connection bottom plate 120 to which the tension member 113 is fixed, and the tension member 113 is fixed through the fixing unit 111. The tension member 113 is not fixed and the tension member 113 is fixed in the connection base plate 120 of the general part may have different sizes of loads to be supported. That is, it is preferable that the general connection bottom plates 120a and 120b provided with the fixing unit 111 are made larger than the general connection connection base plate 120c to support a larger load.

8 is a perspective view of the general connection bottom plate 120 to which the fixing unit 111 is attached. As shown in FIG. 8, the fixing unit 111 is provided to be welded to the general connection base plate 120.

Hereinafter, the sequencing process according to the sequencing method of the present invention will be described in order.

First, a method of connecting the left and right honeycomb girder type precast concrete panel composite beams 100 by installing the joint connection bottom plate 207 will be described. The left and right composite beam 100 is mounted on the left and right sides of the shoe plate 201 and the precast concrete on both sides is formed such that the concrete pouring portion 50 is formed between the precast concrete panels 102 on both sides. The ends of the panel 102 are disposed to face each other at predetermined intervals, and the soul plate 10 is coupled with the shoe plate 201.

Next, the joint connecting base plate 207 is pushed into the space of the lower end of the abdomen 101 from the side of the concrete pouring portion 50. In this case, the lower end of the abdomen 101 of the steel beam is in close contact with the upper surface of the joint connecting bottom plate 207 by using the height adjusting plate 212 attached to the bottom of the joint connecting bottom plate 207. After close contact, the spacer is placed in the clearance gap of the lower portion of the height adjustment plate 212 to be firmly fixed. Next, attach the upper flange connecting plate to the upper flange of the honeycomb girder facing each other at the flange connection and bolt it. In the abdominal connection part, an abdominal connecting plate 204 is attached to the abdomen 101 of the honeycomb girder adjacent to each other and fastened using a bolt. A lower portion of the abdomen 101 of the left and right steel beams and an upper surface of the joint portion connecting base plate 207 are welded to each other. Assembling the point reinforcing bars 208 of the joint portion connecting base plate 207. The formwork is installed around the connection and the concrete 205 is poured into the connection.

Next, an example of a method of installing the fixing unit 111 on the general connection bottom plate 120 of the composite beam 100 and reinforcing the connection unit with the tension member will be described.

The fixing unit 111 on the general connection bottom plates 120a and 120b adjacent to the connection portion of the general connection bottom plate 120 of the composite beam 100 is welded and bonded in advance at the factory to be provided on the connection bottom plate.

One end of the tension member 113 is fixed to the fixing unit 111 on one side, and the middle portion of the tension member 113 is disposed to span the tension member support 114 provided on the upper side of the abdominal connection portion of the composite beam 100 and then the tension member. Tension 113 and the other end is fixed to the fixing unit 111 of the other side to install the tension member 113 tension.

In order to secure a position on the tension member 113, a tension member auxiliary support 112 may be installed between the fixing member 111 and the tension member support 114.

The process of arranging the steel wire in the precast concrete panel 102 and applying prestress by the tension of the steel wire and the method of tensioning the tension member 113 may use a general known method, and a detailed description thereof will be omitted.

When the bridge is constructed using the continuous beam according to the present invention, the amount of generation of the parent moment acting on the connecting portion as well as the static moment acting on the beam can be significantly reduced, and the mold height can be reduced and the span length can be increased. Easy to maintain due to reduced usage

In addition, economical beam cross-section design is possible, and it is possible to increase the running of the bridge by not using the bridge expansion joint which can only be adopted for the bridge of simple beam type. In addition, it is possible to make the connection part more efficient and to improve the workability. In addition, the tensile stress acting on the parent cement and the upper concrete slab generated in the connecting portion can be appropriately alleviated by the resistance of the tension of the tension material, and appropriate measures are also possible for time-dependent effects such as creep and dry shrinkage.

Claims (5)

As a continuous connection structure of the honeycomb girder-type precast concrete panel composite beam 100 having a structure in which the honeycomb girder type steel beam and the precast concrete panel 102 are integrally assembled and synthesized, The steel beams of two neighboring honeycomb girder-type precast concrete panel composite beams 100 are positioned so that the abdomens face each other, and the sole plate 202 made of steel plates on the lower end surface of the precast concrete panel 102, respectively. ) And each soul plate 202 is coupled to a shoe plate 201 installed in the connection portion of the composite beam 100 so that the precast concrete panel 102 has its ends spaced at predetermined intervals. Are arranged integrally connected with each other to lie in; In the spaced spaces between the ends of the facing precast concrete panel 102, a joint connection bottom plate 207 made of steel plates is disposed, and the steel beam abdomen of the above-described both side synthetic beams 100 are disposed so as to face each other. A lower end is integrally coupled with the joint connection bottom plate 207 so that steel beams of the both side synthetic beams 100 are integrally connected to each other; The space between the two precast concrete panels 102 in which the joint connection bottom plate 207 is located is connected to the precast concrete panels 102 of the two composite beams 100 with their ends spaced together. The precast concrete panels 102 on both sides are integrally connected with each other with the joint part bottom plate 207 embedded in the concrete 205; Tension members 113 are disposed at the connection portions of the composite beams 100 on both sides so that both ends thereof are fixed to the lower portion of the steel beams at a predetermined distance from the connecting portion, and the middle portion thereof is supported by the upper portion of the connecting portion of the steel beams. Continuous connection structure of the honeycomb girder type precast concrete panel composite beam, characterized in that configured to apply a compressive force by the tension force to the upper side of the connection portion (100). 2. The tension member (113) according to claim 1, wherein both ends of the tension member (113) are fixed to a fixing member (111) provided at the general connection bottom plate (120) of the honeycomb girder type precast concrete panel composite beam (100) at both sides; The intermediate portion is provided so as to be supported on the upper side of the abdominal connecting plate 204 by the tension member support 114 provided in the abdominal connecting plate 204 for connecting the abdomen of both side composite beam 100, the continuous honeycomb girder. Parent tension acting on the continuous honeycomb girder type precast concrete panel composite beam by tensioning the tension member 113 so that an opposite moment is generated to cancel the parent moment acting on the composite precast concrete panel composite beam. Continuous connection structure of the honeycomb girder type precast concrete panel composite beam, characterized in that to cancel the. According to claim 1 or 2, wherein the stepped upper surface formed in the inner end of the predetermined height of the both sides of the precast concrete panel 102, the joint connecting base plate 207 is located within the step ; The concrete that is poured and filled between the precast concrete panels 102 of both composite beams to include the joint part bottom plate 207 therein is honeycomb girder type precast, characterized in that it is composed of non-concrete concrete 205. Continuous connection structure of concrete panel composite beam. Two honeycomb girder type precast concrete panel composite beams 100 are mounted on the left and right sides of the shoe plate 201 and the lower end of the precast concrete panel 102 of the honeycomb girder type precast concrete panel composite beam 100 is mounted. (A) coupling the sole plate 202 integrally provided on the surface with the shoe plate 201; The joint connecting bottom plate 207 is pushed into the space between the ends of the precast concrete panels 102 of the opposite composite beams 100 facing each other, and the joint connecting bottom plate 207 is moved by using the height adjusting plate 212. Pushing up and bringing the bottom of the steel beam abdomen 101 of the composite beam 100 into close contact with an upper surface of the joint connecting bottom plate 207; (D) connecting the flanges 104 and the abdomen 101 of both steel beams to each other; (E) integrally coupling a lower part of the abdomen 101 of the steel beam in close contact with an upper surface of the joint part connecting base plate 207; The concrete 205 is poured into a space between the ends of both precast concrete panels 102 in which the joint connecting bottom plate 207 is disposed, so that both precast concrete panels 102 and the joint connecting bottom plate 207 are disposed. Integrally coupling and connecting (f); And By placing and tensioning the tension member 113 in the connecting portion of the composite beam 100 on both sides so that both ends are fixed to the lower portion of the steel beam at a position spaced apart from the connecting portion and the middle portion thereof is supported at the upper side of the connecting portion of the steel beam. Method for sequencing the honeycomb girder type precast concrete panel composite beam comprising the step (g) of applying a compressive force by the tension force to the upper side of the connecting portion of the composite beam (100). The method of claim 4, wherein the step (g) is a fixing unit 111 on the general connection bottom plate 120 adjacent to the connection structure of the general connection bottom plate 120 of the honeycomb girder-type precast concrete panel composite beam 100 Combining (h); (I) fixing one end to the fixing unit 111 on one side and arranging the tension member 113 such that the middle portion of the tension member support 114 is provided on the upper side of the abdominal connection portion of the composite beam; And And tensioning the tension member (113) and then fixing it in the fixing unit (111) of the other side. The method of sequencing the honeycomb girder type precast concrete panel composite beam further comprises.